Fungus Fuels Tree GrowthPoplar is the fastest growing hardwood tree in the western United States, making it an energy feedstock of particular interest to the U.S. Department of Energy (DOE). The fungus is almost always found among and within poplar trees, and in an effort to understand its influence on the plant, a team of scientists studied what happens to the tree’s physical traits and gene expression when the fungus is present.

Better Genome Editing for BioenergyCRISPR-Cas9 is a powerful, high-throughput gene-editing tool that can help scientists engineer organisms for bioenergy applications. Cas9 needs guide RNA to lead it to the correct sequence to snip—but not all guides are effective. Researchers created a set of guide RNAs that were effective against 94 percent of the genes in a lipid-prolific yeast.

Cultivating Symbiotic Antarctic MicrobesIn the Proceedings of the National Academy of Sciences, researchers employed multiple microbiology and ‘omics techniques to experimentally determine that Nanohaloarchaeota are not free-living archaea but rather symbionts.

Methane Flux in the AmazonWetlands are the single largest global source of atmospheric methane. This project aims to integrate microbial and tree genetic characteristics to measure and understand methane emissions at the heart of the Amazon rainforest.

Insights into Functional Diversity in NeurosporaThis proposal investigates the genetic bases of fungal thermophily, biomass-degradation, and fungal-bacterial interactions in Sordariales, an order of biomass-degrading fungi frequently encountered in compost and encompassing one of the few groups of thermophilic fungi.

Improving the Cacao Genome and PhytozomeAn updated reference genome for Theobroma cacao Matina 1-6 has now been completed and released by HudsonAlpha scientists, with the help of Mars Wrigley funding. The annotated genome has been updated to a high quality modern standard and includes RNA-seq data. The improved genome is available for comparative purposes on the latest version of the JGI plant portal Phytozome (phytozome-next.JGI.doe.gov).

Mining IMG/M for CRISPR-Associated ProteinsResearchers report the discovery of miniature CRISPR-associated proteins that can target single-stranded DNA. The discovery was made possible by mining the datasets in the Integrated Microbial Genomes and Microbiomes (IMG/M) suite of tools managed by the JGI. The sequences were then biochemically characterized by a team led by Jennifer Doudna’s group at UC Berkeley.

What Happens Underground Influences Global Nutrient CyclesThrough the Facilities Integrating Collaborations for User Science (FICUS) program, the Environmental Molecular Sciences Laboratory (EMSL) and the DOE Joint Genome Institute (JGI) have selected 11 proposals for support from 53 received through a joint research call.

CSP Functional Genomics Call OngoingThe CSP Functional Genomics call is to enable users to perform state-of-the-art functional genomics research and to help them translate genomic information into biological function. Proposals submitted by January 31, 2019 will be part of the next review.

Learning to LookUsing machine learning, JGI researchers combed through more than 70,000 microbial and metagenome datasets, ultimately identifying more than 10,000 inovirus-like sequences compared to the 56 previously known inovirus genomes.

JGI Early Career Researchers in mSystems Special IssueJGI researchers are among the authors who offer perspectives on what the next five years of innovation could look like. In one article, Rex Malmstrom and Emiley Eloe-Fadrosh outline more targeted approaches to reconstruct individual microbes in an environmental sample. In a separate article, Simon Roux makes a pitch for readers to get involved in the developing field of virus ecogenomics.

Hidden Giants in Forest SoilsIn Nature Communications, giant virus genomes have been discovered for the first time in a forest soil ecosystem by JGI and University of Massachusetts-Amherst researchers. Most of the genomes were uncovered using a "mini-metagenomics" approach that reduced the complexity of the soil microbial communities sequenced and analyzed.

Microbial community analysis of three hydrocarbon reservoir cores provides valuable insights for the assessment of reservoir souring potential

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Author(s):

DOI:

10.1016/j.ibiod.2016.09.002

Abstract:

Three hydrocarbon reservoir cores were obtained from a high temperature non-waterflooded offshore reservoir. All three cores were taken from a 56-m section of the same well. Under sterile conditions, DNA was recovered from the inner section of each core and the microbial community profiles were deduced by sequencing the 16S rRNA marker gene. Taxonomic analysis of the Operational Taxonomic Units (OTUs) recovered, identified a high proportion of members from the Oxalobacteraceae family (38.5%) followed by members from the Pseudomonadaceae and Comamonadaceae families (29.1% and 12.8% respectively). Representatives of all these families are known to degrade hydrocarbons as well as to use nitrate as a terminal electron acceptor under anaerobic conditions. Assuming these predominant microorganisms are indigenous to the reservoir and have not been introduced with the drilling fluids they might exhibit a relatively rapid response to nitrate injection for souring control. On the contrary, very few sulfate reducing bacteria (SRBs) were detected in these cores (< 0.01%) suggesting unfavorable conditions to SRB growth. This however may well rapidly change upon seawater injections in the absence of nitrate addition.
This study sets the microbial profiling "baseline" for the prediction of souring through modelling as well as for any upcoming biomonitoring surveys. (C) 2016 Elsevier Ltd. All rights reserved.